JP2021183913A - Sensor device - Google Patents

Abstract

To prevent damage of a piezoelectric element caused by a motion for tightening a screw member to a holder.SOLUTION: A sensor device 1, for detecting a vibration of a measurement target by pushing a tip 21d of a detection needle 21 against the measurement target, comprises: the detection needle 21; a cylindrical holder 22 into which the rear end of the detection needle 21 is inserted; piezoelectric elements 25 and 26 provided in contact with the rear end of the detection needle 21 in the backward direction of the detection needle 21 in a holder 22; a weight 29 provided in contact with the piezoelectric elements 25 and 26 in the backward direction of the piezoelectric elements 25 and 26 in the holder 22, for pushing the piezoelectric elements 25 and 26 against the rear end of the detection needle 21; a screw member 32 provided in the backward direction of the weight 29, for pushing the weight 29 against the piezoelectric elements 25 and 26 side by screwing with the holder 22; and a corotation stopper 37 for preventing a corotation of the weight 29 due to the screwing motion of the screw member 32.SELECTED DRAWING: Figure 2

Description

The technique disclosed in this application relates to a sensor device.

For example, as disclosed in Patent Document 1, a sensor device for detecting vibration by pressing a detection needle against an object to be measured is known. This sensor device includes a cylindrical casing and a vibration detection unit housed in the casing. In the vibration detection unit, a piezoelectric element (including an electrode plate), a weight, a spring member, and the like are sequentially inserted into a cylindrical holder into which the rear end of the detection needle is inserted. In this sensor device, when the tip of the detection needle is pressed against the object to be measured, the vibration of the object to be measured is transmitted to the detection needle and acts on the piezoelectric element as pressure fluctuation to cause voltage fluctuation. Then, a signal related to voltage fluctuation is sent from the electrode plate to the signal processing circuit, and vibration of the object to be measured is detected.

Japanese Patent No. 5933144

By the way, in the vibration detection unit described above, after inserting the piezoelectric element, the weight, etc. into the holder in order, the screw member is tightened to the holder to hold the piezoelectric element, the weight, or the like. In this way, the piezoelectric element is pressed against the rear end of the detection needle with a predetermined force. However, when the screw member is tightened, the weight may rotate and slide with respect to the piezoelectric element (including the electrode plate). Then, if the sliding surface of the weight is rough, the piezoelectric element may be damaged and the vibration detection accuracy may decrease.

The technique disclosed in the present application has been made in view of such circumstances, and an object thereof is to prevent damage to the piezoelectric element due to an operation (screw operation) of tightening a screw member to a holder.

The technique disclosed in the present application includes a detection needle, a holder, a piezoelectric element, a pressing member, a screw member, and a rotation blocking portion, and measures the measurement by pressing the tip of the detection needle against an object to be measured. It is a sensor device that detects the vibration of an object. The holder has a cylindrical shape into which the rear end of the detection needle is inserted. The piezoelectric element is provided behind the detection needle in the holder in contact with the rear end of the detection needle. The pressing member is provided in contact with the piezoelectric element behind the piezoelectric element in the holder, and presses the piezoelectric element against the rear end of the detection needle. The screw member is provided behind the pressing member and is screwed with the holder to press the pressing member toward the piezoelectric element. The rotation blocking portion prevents the rotation of the pressing member due to the screwing operation of the screw member.

According to the technique disclosed in the present application, it is possible to prevent damage to the piezoelectric element due to the operation of tightening the screw member to the holder (screw operation).

FIG. 1 is a front view showing a schematic configuration of a sensor device according to an embodiment. FIG. 2 is a cross-sectional view showing a schematic configuration of a sensor body according to an embodiment. FIG. 3 is an enlarged cross-sectional view showing a main part of the sensor body according to the embodiment. FIG. 4 is an enlarged cross-sectional view showing a main part of the sensor main body according to the first modification of the embodiment. FIG. 5 is an enlarged cross-sectional view showing a main part of the sensor main body according to the second modification of the embodiment.

Hereinafter, embodiments of the present application will be described with reference to the drawings. It should be noted that the following embodiments are essentially preferred examples and are not intended to limit the scope of the techniques disclosed in this application, their applications, or their uses.

The sensor device 1 of the present embodiment shown in FIG. 1 is connected to a fixing device (not shown) and fixed to a measurement object (for example, a steam trap) to detect both vibration and temperature of the measurement object. It is a fixed type sensor. The sensor device 1 is fixed to the object to be measured, for example, in a state of extending in the vertical direction.

The sensor device 1 includes a sensor main body 2, an antenna 3, and a connection shaft 4. The connection shaft 4 is a hollow shaft, and both ends thereof are connected to the sensor body 2 and the antenna 3 by nuts 5 and 6. Although not shown, the antenna 3 has a built-in signal processing circuit and a transmitting unit, and signals related to vibration and temperature of the object to be measured detected by the sensor main body 2 are transmitted.

As shown in FIG. 2, the sensor main body 2 includes a casing 10, a vibration detection unit 20, and a temperature detection unit 40 (thermocouple unit).

The casing 10 is formed in a substantially cylindrical shape and has a large diameter portion 11, a medium diameter portion 12, and a small diameter portion 13. A male screw portion 11a to which the above-mentioned nut 5 is fastened is formed on the outer peripheral surface of the large diameter portion 11. A male screw portion 13a to be fastened to the above-mentioned fixing device is formed on the outer peripheral surface of the small diameter portion 13.

The vibration detection unit 20 includes a detection needle 21, a holder 22, piezoelectric elements 25 and 26, a weight 29 (weight), a spring member 31, a screw member 32, and a rotation blocking portion 37, and is a casing 10. It is inserted into the device to detect (measure) the vibration of the object to be measured.

The detection needle 21 is an elongated rod-shaped member, and a large diameter portion 21a, a medium diameter portion 21b, and a small diameter portion 21c are formed in this order from the rear side. The detection needle 21 is arranged coaxially with the casing 10 and has a tip 21d protruding from the casing 10.

The holder 22 is composed of an inner metal holder 23 and an outer resin holder 24 that houses and holds the metal holder 23. Both the metal holder 23 and the resin holder 24 are formed in a bottomed cylindrical shape and are arranged coaxially with the casing 10.

In the metal holder 23, the large diameter portion 23a, the medium diameter portion 23b, and the small diameter portion 23c having different diameters of the tubular wall are formed in order from the rear side, and the rear end of the detection needle 21 is inserted into the small diameter portion 23c. It is fixed. Specifically, in the detection needle 21, the large diameter portion 21a is located in the medium diameter portion 23b of the metal holder 23, and the rear side of the medium diameter portion 21b is inserted into the small diameter portion 63c of the metal holder 23.

The large diameter portion 21a of the detection needle 21 is formed to have a diameter larger than the inner diameter of the small diameter portion 23c of the metal holder 23, and is in contact with the stepped portion between the medium diameter portion 23b and the small diameter portion 23c of the metal holder 23. There is. Piezoelectric elements 25 and 26, weights 29, spring members 31, and the like are housed in the metal holder 23, and their configurations will be described in detail later.

The resin holder 24 is arranged on the front side of the metal holder 23, and accommodates the small diameter portion 23c and the medium diameter portion 23b of the metal holder 23, and the majority portion of the large diameter portion 23a. Specifically, in the resin holder 24, the large diameter portion 24a and the small diameter portion 24b having different diameters of the cylindrical wall are formed in order from the rear side. In the resin holder 24, the large diameter portion 23a of the metal holder 23 is located in the large diameter portion 24a, and the medium diameter portion 23b and the small diameter portion 23c of the metal holder 23 are located in the small diameter portion 24b. The bottom wall 24c of the resin holder 24 is formed with an insertion hole 24d into which the medium diameter portion 21b of the detection needle 21 is fitted.

The metal holder 23 has two projecting pieces 23d. The projecting piece 23d is a piece that protrudes from the tubular wall of the metal holder 23 large diameter portion 23a and extends in the circumferential direction, and is provided at a position facing each other. On the other hand, in the resin holder 24, two circumferential grooves 24e into which the projecting pieces 23d are inserted are formed on the inner peripheral surface of the tubular wall. The two circumferential grooves 24e are grooves extending in the circumferential direction of the large diameter portion 24a, and are provided at positions facing each other.

The sensor body 2 includes a coil spring 35 that urges the vibration detection unit 20 forward. The vibration detection unit 20 is inserted into the casing 10 so as to be displaceable in the axial direction (that is, the front-rear direction) of the casing 10. The coil spring 35 is arranged behind the vibration detection unit 20 in the casing 10.

One end (rear side end) of the coil spring 35 is supported by the snap ring 36, and the other end (front end) of the coil spring 35 is in contact with the rear end surface of the tubular wall in the resin holder 24. The snap ring 36 is fitted in a groove 11b formed on the inner surface of the large diameter portion 11 of the casing 10 and receives one end of the coil spring 35. The coil spring 35 is configured to urge the vibration detection unit 20 forward by urging the resin holder 24 (holder 22) forward, and to project the tip 21d of the detection needle 21 from the casing 10.

The temperature detection unit 40 includes a contact plate 41 (heat transfer plate) and a holding member 42, and detects (measures) the temperature of the object to be measured. The contact plate 41 is a substantially annular plate member. The holding member 42 holds the small diameter portion 21c of the detection needle 21 and the contact plate 41. The holding member 42 is formed in a substantially cylindrical shape, and is housed (inserted) in the tip end side of the small diameter portion 13 of the casing 10. The contact plate 41 is held at the tip of the holding member 42.

The holding member 42 is formed with one detection needle hole 43 and two thermocouple wire holes 44, 45, each extending in the axial direction. The detection needle hole 43 is a through hole formed in the center of the holding member 42, and the small diameter portion 21c of the detection needle 21 is inserted. The thermocouple holes 44 and 45 are through holes formed at positions shifted by 180 ° with the detection needle hole 43 in between, and two thermocouple wires (not shown) are inserted therethrough. One end of these two thermocouple wires is connected to the contact plate 41, and the other end is connected to the signal processing circuit of the antenna 3. Further, a coil spring 46 for urging the holding member 42 toward the tip end side of the casing 10 is provided in the casing 10.

As shown in FIG. 3, the piezoelectric elements 25 and 26, the weight 29 (weight), and the spring member 31 are contained in the metal holder 23 (holder 22) into which the large diameter portion 21a of the detection needle 21 is inserted. , A screw member 32 and a rotation blocking portion 37 are provided.

Specifically, two piezoelectric elements 25 and 26 are provided behind the detection needle 21 in the small diameter portion 23c of the metal holder 23. The two piezoelectric elements 25 and 26 are integrally provided with electrode plates 27 and 28. More specifically, in the small diameter portion 23c, the first piezoelectric element 25, the first electrode plate 27, the second piezoelectric element 26, and the second electrode plate 28 are arranged in contact with each other in order from the detection needle 21 side. .. The first piezoelectric element 25 is arranged in contact with the rear end (large diameter portion 21a) of the detection needle 21.

A guide portion 23e for holding the outer circumferences of the piezoelectric elements 25 and 26 and the electrode plates 27 and 28 is formed on the inner surface of the small diameter portion 23c of the metal holder 23. Although not shown, the two electrode plates 27 and 28 are connected to the signal processing circuit of the antenna 3 by signal lines, respectively. That is, the signal line is wired from the sensor main body 2 through the connection shaft 4 to the inside of the antenna 3.

The weight 29 is provided behind the piezoelectric elements 25 and 26 in the metal holder 23 in contact with the piezoelectric elements 25 and 26. That is, the weight 29 is provided behind the second electrode plate 28 in contact with the first electrode plate 27. The weight 29 is a pressing member that presses the piezoelectric elements 25 and 26 against the rear end (large diameter portion 21a) of the detection needle 21.

The weight 29 is provided so as to straddle the large diameter portion 23a and the small diameter portion 23b of the metal holder 23. The weight 29 is composed of an integrally formed head 29a and a shaft portion 29b. The head portion 29a is formed in a disk shape coaxial with the axis X of the metal holder 23, and the shaft portion 29b is formed in a rod shape extending coaxially with the axis center X from the head portion 29a toward the detection needle 21. .. The head portion 29a is located at the large diameter portion 23a of the metal holder 23, and the shaft portion 29b is located at the small diameter portion 23b of the metal holder 23 and is in contact with the second electrode plate 28. The weight 29 presses the piezoelectric elements 25 and 26 against the detection needle 21 by its own gravity.

The spring member 31 is provided behind the weight 29 in the metal holder 23. Specifically, the spring member 31 is provided on the large diameter portion 23a of the metal holder 23. The spring member 31 is provided in contact with the head portion 29a of the weight 29. In the present embodiment, the spring member 31 is a disc spring in which two are stacked. The spring member 31 presses the piezoelectric elements 25 and 26 against the detection needle 21 by urging the weight 29 forward.

The screw member 32 is provided behind the weight 29 and is screwed with the metal holder 23 to press the weight 29 toward the piezoelectric elements 25 and 26. Specifically, the screw member 32 is provided in contact with the rotation blocking portion 37 behind the spring member 31 in the large diameter portion 23a of the metal holder 23 and behind the rotation blocking portion 37. That is, in the metal holder 23, a weight 29, a spring member 31, a rotation blocking portion 37, and a screw member 32 are provided in order behind the piezoelectric elements 25 and 26. The screw member 32 is a disk-shaped member having a male screw formed on the outer peripheral surface, and is fixed to the metal holder 23 by being screwed with the female screw portion 23e on the inner surface of the large diameter portion 23a.

More specifically, two screw members 32 are provided and are in contact with each other. Of the two, the screw member 32 on the front side (that is, the screw member 32 in contact with the rotation blocking portion 37) is piezoelectric by its tightening force via the rotation blocking portion 37, the spring member 31, and the weight 29. The elements 25 and 26 are pressed against the detection needle 21. Of the two, the screw member 32 on the rear side has a function of preventing the screw member 32 on the front side from loosening.

The rotation blocking portion 37 prevents the rotation of the weight 29 due to the screwing operation of the screw member 32 (screw member 32 on the front side).

Specifically, the rotation blocking portion 37 is provided between the weight 29 (more specifically, the spring member 31) and the screw member 32 in the metal holder 23. The rotation blocking portion 37 has a base portion 37a and a transmission portion 37b.

The base portion 37a is in contact with the spring member 31 (that is, indirectly in contact with the weight 29). More specifically, the base portion 37a is formed in a disk shape coaxial with the axis X. One surface (front surface) of the base portion 37a is in contact with the spring member 31. That is, the base portion 37a and the spring member 31 are in surface contact with each other. The diameters of the head portion 29a, the spring member 31, and the base portion 37a of the weight 29 are substantially the same as each other, and are slightly smaller than the inner diameter of the large diameter portion 23a of the metal holder 23.

The transmission portion 37b is generated by the screwing operation of the screw member 32 in the pressing force in the axial X direction of the metal holder 23 (hereinafter, also simply referred to as “pressing force”) and the rotation of the metal holder 23 around the axial center X. Of the forces (hereinafter, also simply referred to as "rotational forces"), the pressing force in the X direction of the axial center is transmitted to the weight 29. The screwing operation of the screw member 32 is an operation in which the screw member 32 rotates about the axis X.

More specifically, the transmission portion 37b is integrally formed with the base portion 37a. The transmission portion 37b is configured to make point contact with the screw member 32 (the screw member 32 on the front side) on the axis X of the metal holder 23.

Specifically, the transmission portion 37b projects hemispherically from the other surface (rear side surface) of the base portion 37a toward the screw member 32 side. The transmission portion 37b is formed in the center of the base portion 37a. That is, the center of the transmission unit 37b coincides with the axis X. The protruding end of the transmission portion 37b is in point contact with the lower surface of the screw member 32 (screw member 32 on the front side). The lower surface of the screw member 32 is a flat surface. The contact point P between the transmission portion 37b and the screw member 32 is located on the axis X.

In the sensor device 1 described above, by pressing the tip 21d of the detection needle 21 against the object to be measured and pushing the detection needle 21, the mechanical vibration of the object to be measured is transmitted to the detection needle 21, and the piezoelectric element 25, as a pressure fluctuation, Acts on 26. In response to this, voltage fluctuations occur in the piezoelectric elements 25 and 26, and signals related to the voltage fluctuations are sent from the electrode plates 27 and 28 to the signal processing circuit of the antenna 3 via the signal lines. In this way, the vibration of the object to be measured is detected (measured) by the vibration detection unit 20.

Further, in the sensor device 1, the heat (high temperature heat) of the object to be measured is transmitted to the contact plate 41, and a potential difference is generated between the two thermocouple wires. Then, a signal relating to this potential difference is sent to the signal processing circuit of the antenna 3 to detect (measure) the temperature of the object to be measured. That is, the temperature detection unit 40 of the present embodiment comes into contact with the measurement object by pushing the detection needle 21 and detects the temperature of the measurement object. The numerical values of the vibration and the temperature of the measurement object detected as described above are wirelessly transmitted from the transmitting unit of the antenna 3 to another receiving unit (not shown).

Next, the operation when the screw member 32 is tightened (screwed) to the metal holder 23 will be described. In the metal holder 23 into which the rear end of the detection needle 21 is inserted, the piezoelectric elements 25 and 26 (including the electrode plates 27 and 28), the weight 29, the spring member 31, and the rotation blocking portion 37 are housed in this order. Then, by tightening (screwing) the screw member 32 (screw member 32 on the front side) to the metal holder 23, the weight 29, the spring member 31, the rotation blocking portion 37, and the screw member 32 are brought into close contact with each other. The piezoelectric elements 25 and 26 are pressed against the detection needle 21.

More specifically, by the tightening operation (screw operation) of the screw member 32, the pressing force in the axial center X direction and the rotational force around the axial center X act on the rotation blocking portion 37. Here, since the rotation blocking portion 37 (transmission portion 37b) and the screw member 32 are in point contact at the contact point P on the axis X, the rotational force of the screw member 32 is transmitted to the rotation blocking portion 37. Not done. That is, of the pressing force and the rotational force generated by the tightening operation (screw operation) of the screw member 32, only the pressing force is transmitted to the rotation blocking portion 37.

The pressing force transmitted to the rotation blocking portion 37 is transmitted to the weight 29 via the spring member 31. In this way, the pressing force is transmitted to the weight 29 by the rotation blocking unit 37 (transmission unit 37b), but the rotational force is blocked by the rotation blocking unit 37 (transmission unit 37b). As described above, since the rotational force is not transmitted to the weight 29, the rotation of the weight 29 due to the tightening operation (screw operation) of the screw member 32 is prevented.

In this way, the piezoelectric elements 25 and 26 are pressed against the detection needle 21 by a weight 29, a spring member 31, a rotation blocking portion 37, and a screw member 32 with a predetermined force (initial pressing force). As a result, even if vibrations or forces other than the object to be measured act on the piezoelectric elements 25 and 26 as disturbances, the disturbances can be absorbed and are not affected by the disturbances.

As described above, the sensor device 1 of the above embodiment includes a rotation blocking unit 37 that prevents the weight 29 from rotating due to the screwing operation of the screw member 32. Specifically, the rotation blocking portion 37 is provided between the weight 29 (pressing member) and the screw member 32 in the metal holder 23. Then, the rotation blocking portion 37 transmits the pressing force among the pressing force in the axial center X direction and the rotational force around the axial center X generated by the screwing operation of the screw member 32 to the weight 29. It has a transmission unit 37b.

According to the above configuration, the pressing force generated by the screwing operation of the screw member 32 is transmitted to the weight 29, but the rotational force is not transmitted to the weight 29. That is, the rotational force is cut off. Therefore, it is possible to prevent the weight 29 from rotating due to the screwing operation of the screw member 32. This makes it possible to prevent damage to the piezoelectric elements 25 and 26 due to the weight 29 sliding with respect to the piezoelectric elements 25 and 26 (including the electrode plates 27 and 28). Therefore, it is possible to prevent a decrease in vibration detection accuracy.

Further, the rotation blocking portion 37 further has a base portion 37a that indirectly contacts the weight 29. The transmission portion 37b of the rotation blocking portion 37 is integrally formed with the base portion 37a and is in point contact with the screw member 32 on the axis X of the metal holder 23. According to this configuration, it is possible to realize with a simple configuration that the pressing force is transmitted and the rotational force is cut off.

Further, the transmission portion 37b of the rotation blocking portion 37 projects hemispherically from the base portion 37a. According to this configuration, it is possible to easily realize a configuration in which the transmission portion 37b and the screw member 32 are in point contact on the axis X.

(Modification 1 of the embodiment)
In this modification, in the sensor device 1 of the above embodiment, the arrangement of the spring member and the rotation blocking portion is changed. Here, the points different from the above-described embodiment will be described.

As shown in FIG. 4, the rotation blocking portion 38 of this modification is provided behind the weight 29, and the spring member 31 is provided behind the rotation blocking portion 38. The spring member 31 presses the piezoelectric elements 25 and 26 against the detection needle 21 via the weight 29 by urging the rotation blocking portion 38 forward. The screw member 32 is provided behind the spring member 31 in contact with the spring member 31.

The rotation blocking portion 38 is provided between the weight 29 in the metal holder 23 and the screw member 32 (more specifically, the spring member 31). The rotation blocking portion 38 has a base portion 38a and a transmission portion 38b.

The base 38a is in contact with the spring member 31 (that is, indirectly in contact with the screw member 32). One surface (rear side surface) of the base portion 38a is in contact with the spring member 31. That is, the base portion 38a and the spring member 31 are in surface contact with each other. Similar to the above embodiment, the transmission unit 38b transmits the pressing force among the pressing force and the rotational force generated by the screwing operation of the screw member 32 to the weight 29.

The transmission portion 38b is integrally formed with the base portion 38a. The transmission portion 38b is configured to make point contact with the weight 29 on the axis X of the metal holder 23. Specifically, the transmission portion 38b projects hemispherically from the other surface (front surface) of the base portion 38a toward the weight 29 side. The transmission portion 38b is formed in the center of the base portion 38a. That is, the center of the transmission unit 38b coincides with the axis X. The protruding end of the transmission portion 38b is in point contact with the upper surface 29c of the head portion 29a of the weight 29. The upper surface 29c of the head 29a is a flat surface. The contact point P between the transmission portion 38b and the weight 29 is located on the axis X.

In this modification, the pressing force and the rotational force generated by the tightening operation (screw operation) of the screw member 32 act on the spring member 31. Therefore, the spring member 31 can be pressed against the rotation blocking portion 38 and rotate around the axis X (that is, rotate). A pressing force and a rotational force act from the spring member 31 on the rotation blocking portion 38 (base 38a). Therefore, the rotation blocking portion 38 can be pressed against the weight 29 and rotate around the axis X (that is, rotate).

Here, since the rotation blocking portion 38 (transmission portion 38b) and the weight 29 are in point contact at the contact point P on the axis X, the rotational force of the rotation blocking portion 38 is not transmitted to the weight 29. That is, of the pressing force and the rotational force generated by the tightening operation (screw operation) of the screw member 32, only the pressing force is transmitted to the weight 29. In this way, the pressing force is transmitted to the weight 29 by the rotation blocking unit 38 (transmission unit 38b), but the rotational force is blocked by the rotation blocking unit 38 (transmission unit 38b).

As described above, even in this modification, since the rotational force is not transmitted to the weight 29, it is possible to prevent the weight 29 from rotating due to the screwing operation of the screw member 32. Therefore, it is possible to prevent damage to the piezoelectric elements 25 and 26 due to the weight 29 sliding with respect to the piezoelectric elements 25 and 26 (including the electrode plates 27 and 28). Other configurations, actions and effects are the same as those in the above embodiment.

(Modification 2 of the embodiment)
In this modification, in the sensor device 1 of the modification 1, the rotation blocking portion also serves as the screw member 32 (screw member 32 on the front side). Further, in this modification, the spring member 31 of the above modification 1 is omitted. Here, the points different from the above-mentioned modification 1 will be described.

As shown in FIG. 5, the rotation blocking portion 39 of this modification has a screwing portion 39a and a transmission portion 39b. The screwed portion 39a is screwed with the metal holder 23 (holder 22). The transmission portion 39b is integrally formed with the screw portion 39a. The transmission unit 39b makes point contact with the weight 29 on the axis X of the metal holder 23, and transmits the pressing force in the axis X direction generated by the screwing operation to the metal holder 23 to the weight 29.

The screwed portion 39a is formed in a disk shape coaxial with the axis X, like the base portion 38a of the modification 1. A male screw is formed on the outer peripheral surface of the screwed portion 39a. That is, the rotation blocking portion 39 is fixed to the metal holder 23 by screwing the screwed portion 39a with the female screw portion 23e of the large diameter portion 23a. One surface (rear side surface) of the screwed portion 39a is in contact with the screw member 32. The screw member 32 has a locking function of the rotation blocking portion 39 (screwed portion 39a).

The transmission portion 39b projects hemispherically from the other surface (front surface) of the screwed portion 39a toward the weight 29 side. The transmission portion 39b is formed in the center of the screw portion 39a. That is, the center of the transmission unit 39b coincides with the axis X. The protruding end of the transmission portion 39b is in point contact with the upper surface 29c of the head portion 29a of the weight 29. The contact point P between the transmission portion 39b and the weight 29 is located on the axis X.

In this modification, the screwing operation of the rotation blocking portion 39 generates a pressing force in the axial center X direction and a rotational force around the axial center X. The pressing force of the rotation blocking portion 39 is transmitted to the weight 29 via the transmission portion 39b as in the above-mentioned modification 1. The rotational force of the rotation blocking portion 39 is not transmitted to the weight 29 as in the above-mentioned modification 1. Therefore, even in this modification, it is possible to prevent the weight 29 from rotating due to the screwing operation of the screw member (screw portion 39a). Other configurations, actions and effects are the same as those in the above embodiment.

(Other embodiments)
The technique disclosed in the present application may have the following configurations for the sensor device 1 of the above embodiment and the modified example.

For example, the transmission portions 37b, 38b, 39b of the rotation blocking portions 37, 38, 39 may protrude from the base portions 37a, 38a (screwed portion 39a) in a semi-elliptical shape.

Further, the shape of the transmission portion is not limited to the above-mentioned shape as long as it can make point contact with the weight 29. For example, the shape of the transmission portion may be such that it protrudes from the base portion (screw portion) in a conical or pyramidal shape.

Further, in the above-described embodiment and modification, the transmission portion is provided in the rotating blocking portion, but instead, the transmission portion may be provided in the upper surface of the head of the weight. Further, the transmission unit may be provided in both the rotation blocking unit and the weight.

Further, in the above embodiment, the sensor device 1 that is fixed to the object to be measured and measures vibration or the like has been described, but the technique disclosed in the present application is measured by a worker holding the device by hand and pressing it against the object to be measured. The same effect can be obtained for the handy type sensor device 1.

Further, the sensor device 1 of the present application may omit the temperature detection unit 40 and detect only the vibration of the object to be measured.

The technique disclosed in the present application is useful for a sensor device that detects vibration of a measurement object by pressing a detection needle against the measurement object.

1 Sensor device 21 Detection needle 22 Holder 23 Metal holder (holder)
25, 26 Piezoelectric element 29 Weight (pressing member)
32 Screw members 37, 38 Rotation blocking part 37a, 38a Base part 37b, 38b Transmission part 39 Rotation blocking part 39a Screwing part 39b Transmission part X axis

Claims (6)

With the detection needle,
A cylindrical holder into which the rear end of the detection needle is inserted,
A piezoelectric element provided behind the detection needle in the holder in contact with the rear end of the detection needle.
A pressing member provided behind the piezoelectric element in the holder in contact with the piezoelectric element and pressing the piezoelectric element against the rear end of the detection needle.
A screw member provided behind the pressing member and for pressing the pressing member toward the piezoelectric element side by screwing with the holder.
A rotation blocking portion for preventing the rotation of the pressing member due to the screwing operation of the screw member is provided.
A sensor device characterized in that vibration of a measurement object is detected by pressing the tip of the detection needle against the measurement object. In the sensor device according to claim 1,
The rotation blocking portion is provided between the pressing member and the screw member in the holder, and the pressing force in the axial direction of the holder and the pressing force of the holder generated by the screwing operation of the screw member. A sensor device comprising a transmission unit that transmits the pressing force among the rotational forces around the axis to the pressing member. In the sensor device according to claim 2,
The rotation blocking portion further has a base portion that is in direct or indirect contact with the pressing member.
The sensor device is characterized in that the transmission portion is integrally formed with the base portion and is in point contact with the screw member on the axis of the holder. In the sensor device according to claim 2,
The rotation blocking portion further has a base portion that is in direct or indirect contact with the screw member.
The sensor device is characterized in that the transmission portion is integrally formed with the base portion and is in point contact with the pressing member on the axis of the holder. In the sensor device according to claim 3 or 4.
The sensor device is characterized in that the transmission portion projects from the base portion in a hemispherical or semi-elliptical shape. In the sensor device according to claim 1,
The rotation blocking part is
It also serves as the screw member.
The screwed portion to be screwed with the holder and
It is integrally formed with the screwed portion, and at the same time, it makes point contact with the pressing member on the axial center of the holder, and transmits the pressing force in the axial direction of the holder generated by the screwing operation to the holder to the pressing member. A sensor device characterized by having a transmission unit.

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